CN112876251A

CN112876251A - High-performance low-dielectric microwave ceramic prepared based on cold sintering technology and method

Info

Publication number: CN112876251A
Application number: CN202110254894.7A
Authority: CN
Inventors: 刘兵; 黄玉辉; 金丁豪; 宋开新
Original assignee: Hangzhou Dianzi University
Current assignee: Hangzhou Dianzi University
Priority date: 2021-03-09
Filing date: 2021-03-09
Publication date: 2021-06-01

Abstract

The invention discloses a method for preparing high-performance low-dielectric microwave ceramic based on a cold sintering technology, which comprises the following steps: (1) weighing appropriate amount of BaF₂Mixing the raw materials with deionized water with the weight percent of not more than 25 percent; (2) putting the solid-liquid mixed powder obtained in the step (1) into a cylindrical die, and simultaneously putting the cylindrical die into a hot press for cold sintering to obtain a ceramic green body; (3) putting the ceramic green body obtained in the step (2) into an oven at 80-200 ℃ for drying until the weight is constant; (4) putting the ceramic green body in the step (3) into a high-temperature sintering furnace, and annealing at 700-950 ℃ to obtain compact BaF₂Microwave dielectric ceramics. BaF prepared by the invention₂The compactness of the ceramic can reach 98 percent, the quality factor can be improved by over 53.4 percent compared with the quality factor of the ceramic prepared by the traditional solid phase sintering method, and the ceramic can be used as an antenna substrate and a resonator in the field of 5G high-frequency communicationAnd the like, and has wide application prospect in electronic components.

Description

High-performance low-dielectric microwave ceramic prepared based on cold sintering technology and method

Technical Field

The invention belongs to the technical field of wireless communication and electronic ceramic material manufacturing, and particularly relates to a microwave dielectric ceramic which is prepared based on a cold sintering technology and has high performance and a low dielectric constant and a preparation method thereof.

Background

The microwave dielectric ceramic is a ceramic material which is used as a dielectric material in a microwave frequency band circuit and can perform one or more functions. Microwave dielectric ceramics are used as key materials in mobile communication components (such as resonators, filters, dielectric substrates and dielectric antennas), and are widely applied to many technical fields of microwave technology, such as mobile phones, satellite base stations, satellite broadcasting, radars and the like.

In recent years, with the rapid development of wireless communication technology and the gradual exhaustion of microwave low-frequency band resources, the frequency band used for wireless communication is gradually expanding from the ISM frequency band to the millimeter wave frequency band. In order to meet the communication requirement of the millimeter wave frequency band, the dielectric constant (epsilon) is low_r<10) And a high quality factor (Qf)>40000GHz) have received much attention from people. Low epsilon_rThe delay of microwave signal transmission can be reduced, and the signal response and transmission speed of the microwave device are improved; the high Qf value can enhance the frequency-selective characteristic of the device and reduce the energy transfer loss. In addition, with the increasing requirements of people on information transmission content, speed, quality and the like, new generation high frequency communication technologies such as 5G mobile communication, internet of things (IoT) technology and the like are emerging. Therefore, there is a need to develop a batch of high quality microwave dielectric ceramic materials with low dielectric constant.

BaF₂Is a material with low dielectric constant and high quality factor, and is first in BaF₂The research result of the single crystal shows that the dielectric constant is about 7, and the Qf value can reach more than 50000 GHz. However, BaF₂The single crystal is very expensive and cannot be widely popularized and used. BaF, on the other hand₂BaF with lower surface free energy of crystal grains and sintered by using traditional solid phase method₂The ceramic does not achieve the desired densification (less than 90% densification). The cold sintering technology is a new ceramic densification technology emerging in recent years, and the densification sintering of ceramic can be realized under certain temperature and pressure conditions after specific ceramic powder is mixed with specific solvents (such as water, ethanol and the like). Therefore, the development of novel BaF based on cold sintering technology₂Ceramic preparation process to obtain low-cost high-performance BaF₂Ceramics have become a significant application requirement. Based on the technical scheme, the invention is provided.

Disclosure of Invention

For BaF₂The invention provides a high-performance low-dielectric-constant BaF prepared based on a cold sintering technology, and meets the requirement of improving ceramic compactness and microwave dielectric property₂Microwave ceramics and methods thereof.

In order to achieve the purpose, the invention adopts the following technical scheme:

the method for preparing the high-performance low-dielectric microwave ceramic based on the cold sintering technology comprises the following steps:

(1) mixing materials: weighing appropriate amount of BaF₂Mixing the raw materials with deionized water with the weight percent of not more than 25 percent;

(2) and (3) cold sintering: and placing the obtained solid-liquid mixed powder into a cylindrical die, and simultaneously placing the cylindrical die into a hot press for cold sintering.

(3) Drying: putting the ceramic green body obtained in the step (2) into an oven with the temperature of 80-200 ℃ for drying until the weight is constant, and removing possible residual moisture in the sample;

(4) annealing treatment: putting the ceramic green body in the step (3) into a high-temperature sintering furnace, and annealing at 700-950 ℃ to obtain compact BaF₂Microwave dielectric ceramics.

Preferably, after the step (4), the method further comprises the following steps: (5) subsequent grinding and polishing: subjecting the BaF of the step (4)₂The surface of the ceramic block is respectively polished on 800 meshes of sand paper, 1000 meshes of sand paper and 1500 meshes of sand paper, and the ceramic with smooth surface is obtained.

As a preferable scheme, step (2), the working temperature (100 ℃ < T <200 ℃), pressure (100MPa < P <800MPa) and time (0.5h < T <4h) of a hot press are controlled in the cold sintering process, and a primary compact ceramic green body is obtained after the cold sintering is finished;

preferably, before the step (1), the method further comprises the following steps: mixing raw material BaF₂Putting the mixture, zirconia ball milling medium and absolute ethyl alcohol solvent into a ball mill for continuous ball milling (preferably more than 6 h) to obtain uniform and fine BaF₂Powder; wherein the raw material is zirconium oxideThe mass ratio of the ball milling medium to the absolute ethyl alcohol is 1: 5: 3.

preferably, the ball mill is a planetary ball mill, and the rotating speed is controlled to be 180-250 r/min.

Preferably, in the step (2), the temperature raising process of the cold sintering includes: the temperature is raised to the set temperature at the speed of 5 ℃/min.

Preferably, the annealing process comprises: heating to 950 ℃ at the speed of 5 ℃/min, and annealing for 3 h; then the temperature is reduced to 400 ℃ at the speed of 2 ℃/min, and finally the temperature is reduced to the room temperature along with furnace cooling.

Preferably, the BaF₂Has a purity of 99.99%, and the cylindrical green compact has a diameter of 12mm and a height of 5 mm.

The invention also provides a microwave dielectric ceramic with excellent microwave dielectric property, which is prepared by the method in any technical scheme and has the dielectric constant of 7<ε_r<7.3 quality factor Qf value 72350GHz<Qf<82320GHz, temperature coefficient of resonance frequency tau_f～–110ppm/℃。

Compared with the prior art, the invention has the beneficial effects that:

the preparation method adopted by the invention is a cold sintering method, the method is simple, the cold sintering temperature required by the preparation is lower than 200 ℃, the subsequent annealing temperature is lower than 900 ℃, and the required temperature is lower, so that the production cost is favorably reduced. In addition, the required temperature is lower than the melting point of common metal electrodes such as silver (960 ℃) and copper (1080 ℃), and the ceramic material can be used as a low-temperature co-fired ceramic system with high performance. Finally, BaF prepared by the invention₂The density of the ceramic can reach 98 percent, the quality factor can be improved by over 53.4 percent compared with the traditional solid-phase sintering method, and the ceramic has wide application prospect in electronic components such as antenna substrates, resonators and the like in the field of 5G high-frequency-band communication.

Drawings

FIG. 1 shows high performance low dielectric BaF of examples 1 to 5 of the present invention₂A ceramic XRD spectrum;

FIG. 2 shows high performance low dielectric BaF of examples 1 to 5 of the present invention₂The relative density of the ceramic and the microwave dielectric property map;

FIG. 3 shows high performance low dielectric BaF of examples 2 to 5 of the present invention₂A Scanning Electron Microscope (SEM) image of the ceramic;

FIG. 4 shows high performance low dielectric BaF of example 4 of the present invention₂Co-firing SEM and elemental analysis of the ceramic and silver metal electrodes.

Detailed Description

The technical solution of the present invention is further described below by means of specific examples.

Example 1: (CS group)

This example, as a control group, used a Conventional solid phase reaction method (CS: computational Sintering) to prepare BaF₂Ceramics and their properties are compared with BaF prepared by cold sintering of the invention₂Ceramics were compared. The preparation method of this example includes the following steps:

(1) mixing raw material BaF₂Putting the mixture, zirconia ball milling medium and absolute ethyl alcohol solvent into a ball mill for continuous ball milling for more than 6 hours to obtain uniform and fine BaF₂Powder; wherein the mass ratio of the raw materials, the zirconia ball-milling medium and the absolute ethyl alcohol is 1: 5: 3. the ball mill is a planetary ball mill, and the rotating speed is controlled to be 180-250 r/min.

(2) Tabletting: weighing appropriate amount of BaF₂The raw materials are put into a cylindrical die and pressed under a tablet press to obtain BaF₂A ceramic green body. BaF₂The purity of (2) was 99.99%, and the diameter of the cylindrical green compact was 12mm and the height was 5 mm.

(3) And (3) sintering: placing the ceramic green body obtained in the above steps in a high temperature furnace, raising the temperature to 900 ℃ at a heating rate of 5 ℃/min, and annealing for 3h to obtain BaF₂And (3) controlling the program to cool to 400 ℃ at the speed of 2 ℃/min after the annealing of the ceramic, then cooling to room temperature along with the furnace, and taking out the sample. The sintering treatment process comprises the following steps: heating to 900 ℃ at the speed of 5 ℃/min, and sintering for 3 h; then the temperature is reduced to 400 ℃ at the speed of 2 ℃/min, and finally the temperature is reduced to the room temperature along with furnace cooling.

(4) Subsequent grinding and polishing: BaF obtained by the above steps₂The surface of the ceramic block is respectively polished on 800 meshes of sand paper, 1000 meshes of sand paper and 1500 meshes of sand paper, and the ceramic with smooth surface is obtained.

BaF obtained in this example₂The density of the ceramic was 0.92.

BaF obtained in this example₂Dielectric constant (. epsilon.) of ceramic_r) Was 6.72.

BaF obtained in this example₂The quality factor (Qf) of the ceramic was 53654 GHz.

BaF obtained in this example₂Temperature coefficient of resonance frequency (tau) of ceramic_f) Is-85 ppm/DEG C.

Example 2: (125MPa)

The cold sintering pressure selected in this example was 125MPa, the temperature was 150 ℃ and the time was 1 h. For comparison with the examples at different subsequent cold sintering pressures, the example is indicated at 125MPa and is prepared by the following steps:

(2) and (3) cold sintering: and placing the obtained solid-liquid mixed powder into a cylindrical die, and simultaneously placing the cylindrical die into a hot press for cold sintering. Controlling the working pressure P of a hot press to 125MPa, the temperature T to 150 ℃ and the time T to 1h in the cold sintering process, and obtaining a primary compact ceramic green body after the cold sintering is finished;

(3) drying: putting the ceramic green body obtained in the step (2) into a 200 ℃ oven to be dried to constant weight, and removing possible residual moisture in the sample;

(4) annealing treatment: putting the ceramic green body obtained in the step (3) into a high-temperature sintering furnace, and annealing for 3 hours at the temperature of 900 ℃ to obtain compact BaF₂Microwave dielectric ceramics;

(5) subsequent grinding and polishing: subjecting the BaF of the step (4)₂The surface of the ceramic block is respectively polished on 800 meshes of sand paper, 1000 meshes of sand paper and 1500 meshes of sand paper, and the ceramic with smooth surface is obtained.

Before the step (1), the method further comprises the following steps: mixing raw material BaF₂Putting the mixture, zirconia ball milling medium and absolute ethyl alcohol solvent into a ball mill for continuous ball milling for more than 6 hours to obtain uniform and fine BaF₂Powder; wherein the mass ratio of the raw materials, the zirconia ball-milling medium and the absolute ethyl alcohol is 1: 5: 3.

the ball mill is a planetary ball mill, and the rotating speed is controlled to be 180-250 r/min.

In the step (2), the temperature rising process of cold sintering comprises the following steps: the temperature is raised to the set temperature at the speed of 5 ℃/min.

The annealing treatment process comprises the following steps: heating to 900 ℃ at the speed of 5 ℃/min, and annealing for 3 h; then the temperature is reduced to 400 ℃ at the speed of 2 ℃/min, and finally the temperature is reduced to the room temperature along with furnace cooling.

BaF₂The purity of (2) was 99.99%, and the diameter of the cylindrical green compact was 12mm and the height was 5 mm.

BaF obtained in this example₂The density of the ceramic was 0.95.

BaF obtained in this example₂Dielectric constant (. epsilon.) of ceramic_r) It was 7.05.

BaF obtained in this example₂The quality factor (Qf) of the ceramic was 72350 GHz.

BaF obtained in this example₂Temperature coefficient of resonance frequency (tau) of ceramic_f) Is-107 ppm/. degree.C.

Example 3: (250MPa)

The cold sintering pressure selected in this example was 250MPa, and the remaining process conditions were the same as in example 2. The preparation process comprises the following steps:

(2) and (3) cold sintering: and placing the obtained solid-liquid mixed powder into a cylindrical die, and simultaneously placing the cylindrical die into a hot press for cold sintering. Controlling the working pressure P of the hot press to be 250MPa, the temperature T to be 150 ℃ and the time T to be 1h in the cold sintering process, and obtaining a primary compact ceramic green body after the cold sintering is finished;

BaF obtained in this example₂The density of the ceramic was 0.96.

BaF obtained in this example₂Dielectric constant (. epsilon.) of ceramic_r) It was 7.09.

BaF obtained in this example₂The quality factor (Qf) of the ceramic was 80400 GHz.

BaF obtained in this example₂Temperature coefficient of resonance frequency (tau) of ceramic_f) At-106 ppm/deg.C.

Example 4: (375MPa)

The cold sintering pressure selected in this example was 375MPa, and the remaining process conditions were the same as in example 2. The preparation process comprises the following steps:

(1) mixing materials: weighing appropriate amount of BaF₂Mixing raw materials (with the purity of 99.99%) with deionized water with the weight percent of not more than 25%;

(2) and (3) cold sintering: and placing the obtained solid-liquid mixed powder into a cylindrical die, and simultaneously placing the cylindrical die into a hot press for cold sintering. Controlling the working pressure P of the hot press to 375MPa, the temperature T to 150 ℃ and the time T to 1h in the cold sintering process, and obtaining a primary compact ceramic green body after the cold sintering is finished;

BaF obtained in this example₂The density of the ceramic was 0.96.

BaF obtained in this example₂Dielectric constant (. epsilon.) of ceramic_r) It was 7.19.

BaF obtained in this example₂The quality factor (Qf) of the ceramic was 80120 GHz.

BaF obtained in this example₂Temperature coefficient of resonance frequency (tau) of ceramic_f) Is-108 ppm/. degree.C.

Example 5: (500MPa)

The cold sintering pressure selected in this example was 500MPa, and the remaining process conditions were the same as in example 2. The preparation process comprises the following steps:

(2) and (3) cold sintering: and placing the obtained solid-liquid mixed powder into a cylindrical die, and simultaneously placing the cylindrical die into a hot press for cold sintering. Controlling the working pressure P of a hot press to be 500MPa, the temperature T to be 150 ℃ and the time T to be 1h in the cold sintering process, and obtaining a primary compact ceramic green body after the cold sintering is finished;

BaF₂Has a purity of 99.99%, and the cylindrical green compact has a diameter of 12mm and a height of 5 mm.

BaF obtained in this example₂The density of the ceramic is 0.98.

BaF obtained in this example₂Dielectric constant (. epsilon.) of ceramic_r) It was 7.3.

BaF obtained in this example₂The quality factor (Qf) of the ceramic was 82320 GHz.

BaF obtained in this example₂Temperature coefficient of resonance frequency (tau) of ceramic_f) At-109 ppm/deg.C.

FIG. 1 is an XRD pattern of the samples of examples 1-5. As can be seen, in each example, a single-phase BaF was successfully prepared₂A ceramic.

The relative density of the samples in the examples was measured by Archimedes drainage method, and the microwave dielectric properties at the resonant frequency of the cylindrical ceramic were measured by the dielectric resonance cavity method proposed by Hakki-Coleman, the specific property pairs being shown in FIG. 2. BaF obtained by the Cold sintering Process in the above five examples₂Ceramic compactness and dielectric constant (epsilon)_r) Compared with the quality factor (Qf) value of the traditional solid phase method control group (example 1), the method has the advantage that the cold sintering process adopted by the invention has very obvious effect on improving the ceramic compactness and the microwave performance. Example 5 preparation of BaF₂The ceramic has the highest relative density, the value of the ceramic is 98%, and the quality factor Qf value of the ceramic is as high as 82320GHz, and compared with the control group of example 1, the Qf value is improved by 53.4%.

Further, FIG. 3 shows BaF in examples 2 to 5₂SEM photograph of surface of ceramic, from which BaF produced by cold sintering₂Ceramics have a dense microstructure, which also corresponds to their excellent densification.

Finally, FIG. 4 shows the BaF obtained in example 5₂SEM photograph of co-firing ceramic and silver electrodes. As can be seen, BaF₂The silver electrode does not generate chemical reaction after being co-fired at 900 ℃, obvious ceramic-metal boundaries exist, and the conclusion is further proved by the results of line scanning energy spectrum data. This demonstrates that the high performance BaF prepared by the present invention₂The ceramic can simultaneously meet the technical requirements of low temperature co-fired ceramic (LTCC) and multilayer co-fired ceramic (MLCC).

In the above embodiments and alternatives thereof, the cold sintering pressure in step (2) may also be 100MPa, 200MPa, 300MPa, 400MPa, or the like.

In the above embodiments and alternatives, the cold sintering temperature in step (2) may also be 100 ℃, 125 ℃, 175 ℃, 200 ℃, etc.

In the above embodiments and alternatives thereof, the cold sintering time in step (2) may also be 2h, 3h, 4h, etc.

In the above embodiments and alternatives, the temperature for drying in step (3) may also be 80 ℃, 100 ℃, 120 ℃, 160 ℃, etc.

In the above embodiments and alternatives, the annealing temperature in step (4) may also be 800 ℃, 825 ℃, 875 ℃, 925 ℃, etc.

The invention relates to a high-performance low-dielectric microwave ceramic prepared based on a cold sintering technology and a method thereof, wherein the adopted raw material is high-purity BaF₂Powder of BaF₂Mixing the raw materials with deionized water not higher than 25 wt%, placing the solid-liquid mixed powder in a hot press, and controlling the working temperature of the hot press (100 deg.C)<T<200 ℃ C.), pressure (100 MPa)<P<800MPa), time (0.5 h)<t<4h) A primary dense ceramic green body is obtained. Finally, the obtained green body is placed in a high-temperature furnace, and annealing treatment is carried out in the temperature range of 700-950 ℃ to obtain compact BaF₂Microwave dielectric ceramics. The microwave ceramic obtained by the preparation method disclosed by the invention has excellent dielectric property: 7<ε_r<7.3,72350GHz<Qf<82320GHz,τ_f110 ppm/. degree.C. Compared with the traditional solid-phase ceramic reaction method, the Qf value obtained by the method can be improved by over 53.4 percent, and the method can be widely applied to electronic components such as antenna substrates, resonators and the like in the field of 5G high-frequency band communication.

The above description of the embodiments is only intended to facilitate the understanding of the method of the invention and its core ideas. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims

1. A method for preparing high-performance low-dielectric microwave ceramics based on a cold sintering technology is characterized by comprising the following steps:

(1) weighing appropriate amount of BaF₂Mixing the raw materials with deionized water with the weight percent of not more than 25 percent;

(2) putting the solid-liquid mixed powder obtained in the step (1) into a cylindrical die, and simultaneously putting the cylindrical die into a hot press for cold sintering to obtain a ceramic green body;

(3) putting the ceramic green body obtained in the step (2) into an oven at 80-200 ℃ for drying until the weight is constant;

(4) putting the ceramic green body in the step (3) into a high-temperature sintering furnace, and annealing at 700-950 ℃ to obtain compact BaF₂Microwave dielectric ceramics.

2. The method for preparing a high-performance low-dielectric microwave ceramic based on a cold sintering technique according to claim 1, further comprising the step (5) of subjecting the BaF of the step (4) to a heat treatment₂The surface of the ceramic block is respectively polished on 800 meshes of sand paper, 1000 meshes of sand paper and 1500 meshes of sand paper, and the ceramic with smooth surface is obtained.

3. The method for preparing high-performance low-dielectric microwave ceramics based on the cold sintering technology as claimed in claim 1, wherein in the step (2), the working temperature of the hot press is controlled to be 100 ℃ and < T <200 ℃, the pressure is controlled to be 100MPa and < P <800MPa, the time is controlled to be 0.5h and < T <4h in the cold sintering process, and a primary compact ceramic green body is obtained after the cold sintering is finished.

4. The method for preparing high-performance low-dielectric microwave ceramics based on cold sintering technology according to any one of claims 1-3, wherein the step (1) is preceded by the following steps: mixing raw material BaF₂Putting the mixture, zirconia ball milling medium and absolute ethyl alcohol solvent into a ball mill for continuous ball milling to obtain uniform and fine BaF₂And (3) powder.

5. The method for preparing high-performance low-dielectric microwave ceramics based on cold sintering technology as claimed in claim 4, wherein the raw material BaF₂The mass ratio of the zirconia ball milling medium to the absolute ethyl alcohol is 1: 5: 3.

6. the method for preparing the high-performance low-dielectric microwave ceramic based on the cold sintering technology as claimed in claim 4, wherein the ball mill is a planetary ball mill, and the rotation speed is controlled to be 180-250 r/min.

7. The method for preparing high-performance low-dielectric microwave ceramics based on cold sintering technology according to any one of claims 1 to 3, wherein in the step (1), BaF₂The purity of the starting material was 99.99%.

8. The method for preparing high-performance low-dielectric microwave ceramics based on the cold sintering technology as claimed in claim 1 or 3, wherein in the step (2), the temperature rising process of the cold sintering comprises: the temperature is raised to the set temperature at the speed of 5 ℃/min.

9. The method for preparing high-performance low-dielectric microwave ceramics based on the cold sintering technology as claimed in claim 1 or 2, wherein in the step (4), the annealing process comprises: heating to 950 ℃ at the speed of 5 ℃/min, and annealing for 3 h; then the temperature is reduced to 400 ℃ at the speed of 2 ℃/min, and finally the temperature is reduced to the room temperature along with furnace cooling.

10. A high performance low dielectric microwave ceramic prepared by the process of any of claims 1 to 9 wherein the dielectric constant is 7<ε_r<7.3 quality factor Qf value 72350GHz<Qf<82320GHz, temperature coefficient of resonance frequency tau_f～–110ppm/℃。